RU149870U1 - STEAM GENERATOR - Google Patents

Abstract

1. A steam generator comprising a housing, inlet and outlet manifolds with a horizontal bundle of heat exchanger tubes attached to them, an inlet manifold baffle consisting of vertically arranged side sheets and a longitudinal sheet, an outlet manifold baffle consisting of vertically arranged side sheets and a longitudinal sheet, immersed hole a sheet installed in the upper part of the housing a steam receiving hole sheet containing a frame and horizontally arranged sheets with perforation and vertically fixed thereon located end sheets with perforation, and a steam outlet pipe, characterized in that the input manifold baffle and the outlet manifold baffle of the steam receiving hole sheet are perforated, wherein the joints of the longitudinal sheet with the side sheets of the input manifold baffle and the joints of the longitudinal sheet with the side sheets the outlet manifold walls are rounded. 2. The steam generator according to claim 1, characterized in that on the side sheets of the inlet manifold baffle and on the side sheets of the outlet manifold baffle, perforation is performed on the windward side with respect to the flow movement inside the duct of the steam receiving hole sheet. 3. The steam generator according to claim 1, characterized in that on the side sheets of the inlet manifold baffle and on the side sheets of the outlet manifold baffle, perforation is performed on the leeward side with respect to the flow movement inside the duct of the vapor receiving hole sheet. 4. The steam generator according to claim 1, characterized in that on the longitudinal sheet of the baffle of the input manifold and on the longitudinal sheet of the baffle of

Description

The utility model relates to nuclear energy and is intended to generate steam at nuclear power plants.

A steam generator is known from the prior art (“The Past and Future of Horizontal Steam Generators” by NB Trunov, B. I. Lukasevich, V. V. Sotskov, S. A. Harchenko, FSUE OKB GIDROPRESS, Podolsk, p. 15 -21), comprising a housing, an input and output collectors with a horizontal bundle of heat exchange tubes attached to them, an inlet manifold baffle, an outlet manifold baffle, an immersed hole sheet, a vapor receiving hole sheet installed in the upper part of the housing, containing a frame and horizontally located sheets fixed to it with perf oration and vertically located end sheets, and pipes for the removal of steam. The baffle of the inlet manifold consists of vertically arranged side sheets and a longitudinal sheet, the baffle of the outlet manifold consists of vertically arranged side sheets and a longitudinal sheet.

The disadvantages of the known steam generator are the large unevenness of the load of the evaporation mirror, which leads to unreliable operation of the device as a whole.

A steam generator is known from the prior art (RF patent for utility model No. 57425, IPC F22B 1/02, published 10.10.2006), adopted as a prototype of the claimed utility model. A well-known steam generator comprises a housing, an input and output collectors with a horizontal bundle of heat-exchange tubes attached to them, an intake manifold baffle, an output manifold baffle, an immersed hole sheet, a steam receiving hole sheet installed in the upper part of the housing, containing a frame and horizontally arranged perforated sheets fixed thereon and vertically arranged end sheets with perforation, and a steam outlet pipe. The baffle of the inlet manifold consists of vertically arranged side sheets and a longitudinal sheet, the baffle of the outlet manifold consists of vertically arranged side sheets and a longitudinal sheet.

A disadvantage of the known steam generator is that due to the concentrated removal of steam from the body of the steam generator, its vapor-receiving hole sheet does not provide uniform steam flow over the area of the evaporation mirror. Such a concentrated exit of steam from the body of the steam generator leads to high flow rates, oblique steam flow around the vertical cylindrical inlet and outlet headers, and, as a result, the appearance of vortex structures in the steam space of the steam generator. High local steam flow rates at the inlet of the steam outlet lead to a decrease in static pressure, which in turn increases the flow rate in the steam space of the steam generator in front of the vapor receiving hole sheet opposite the steam outlet pipe. Vortex structures also distort a uniform ascending field of steam flow rates in the steam space of the steam generator, which leads to disruption of the gravitational separation process (moisture deposition) and, as a result, the normalized value of steam humidity at the outlet of the steam generator is exceeded.

The objective of the utility model is to provide a more uniform steam flow over the area of the evaporation mirror, directed upward flow without the formation of areas with unacceptably high steam flow rates, and a decrease in the hydraulic resistance of the steam removal system from the steam generator body.

The technical result of the utility model is to increase the operational reliability of the steam generator by reducing the hydraulic resistance of the steam removal path and increasing the efficiency of the vapor receiving hole sheet.

The essence of the utility model lies in the fact that the steam generator comprises a housing, an input and output collectors with a horizontal bundle of heat exchange pipes attached to them, an intake manifold baffle, an output manifold baffle, an immersed hole sheet, a vapor receiving hole sheet installed in the upper part of the housing, containing a frame and fixed on it are horizontally arranged sheets with perforation and vertically located end sheets with perforation, and a steam outlet pipe. The fence of the inlet manifold consists of vertically arranged side sheets and a longitudinal sheet made with perforation. The outlet manifold baffle consists of vertically arranged side sheets and a longitudinal sheet made with perforation. The joints of the longitudinal sheet with the side sheets of the input manifold baffle and the joints of the longitudinal sheet with the side sheets of the outlet manifold baffle are rounded.

In this case, the perforation of the sheets of the baffles can be performed in any possible combination with respect to the direction of the flow inside the duct of the vapor receiving hole sheet, in particular, the perforation is performed:

- on the side sheets of the inlet manifold baffle and on the side sheets of the outlet manifold baffle from the windward side with respect to the flow movement inside the duct of the vapor receiving hole sheet;

- on the side sheets of the inlet manifold baffle and on the side sheets of the outlet manifold baffle on the leeward side with respect to the flow movement inside the duct of the vapor receiving hole sheet;

- on the longitudinal sheet of the baffle of the inlet manifold and on the longitudinal sheet of the baffle of the outlet manifold on the windward side with respect to the movement of the flow inside the duct of the vapor receiving hole sheet;

- on the longitudinal sheet of the baffle of the inlet manifold and on the longitudinal sheet of the baffle of the outlet manifold on the leeward side with respect to the movement of the flow inside the duct of the vapor receiving hole sheet.

The technical result is achieved due to the perforation of the longitudinal and side sheets of the baffle of the input and output headers, as well as by rounding the joints of the longitudinal and side sheets of the baffle of the inlet and outlet headers, which reduce the influence of the concentrated output in the vapor space of the steam generator in the form of a branch pipe steam, reduce hydraulic resistance during the flow of steam inside the duct of the steam receiving hole sheet, increase the flow area and, as a result, the mind reduce the total hydraulic resistance of the entire system for removing steam from the body of the steam generator.

The utility model is illustrated by the following drawings.

In FIG. 1 shows a steam generator, where: 1 - the case of the steam generator, 2 - the inlet manifold, 3 - heat transfer pipes, 4 - the outlet manifold, 5 - the submerged hole sheet, 6 - the steam space, 7 - the steam inlet hole sheet, 8 - the steam outlet pipe.

In FIG. 2 shows the Α-A section of the steam generator, illustrating the baffle of the input and output collectors (side view), where: 1 is the steam generator housing, 7 is the steam receiving hole sheet, 8 is the steam outlet pipe, 9 is the side plate of the baffle, 10 is the longitudinal sheet of the baffle.

In FIG. 3 shows a section B-B of a steam generator illustrating a steam receiving hole sheet known in the art (top view), where 7 is a steam receiving hole sheet, 9 is a side sheet of a partition, 10 is a longitudinal sheet of a partition.

In FIG. 4 shows a section B-B of a steam generator illustrating a vapor receiving hole sheet in which the joints of the longitudinal and side sheets of the input manifold baffle and the joints of the longitudinal and side sheets of the output manifold baffle are rounded (top view), where 7 is the vapor receiving hole sheet, 9 - side sheet of the septum, 10 - longitudinal sheet of the septum.

The case of the steam generator 1 (see Fig. 1) is a welded horizontal cylindrical vessel with elliptical bottoms. The housing of the steam generator 1 is equipped with a pipe 8 steam, located in its upper part. In addition, the input 2 and output 4 collectors, which are vertical cylindrical vessels, are attached to the body of the steam generator 1. The inlet manifold 2 is used for supplying the heat carrier to the heat exchanger tubes 3, the outlet manifold 4 is used to discharge the heat carrier from the heat exchanger tubes 3. The bundle of U-shaped heat exchanger tubes 3 is located horizontally and fixed with its ends to the collectors 2 and 4. The submerged hole sheet 5 is made flat with perforation, located horizontally above the bundle of heat transfer tubes 3 and attached to the body of the steam generator 1. The vapor-receiving hole sheet 7 is made flat with perforation, located horizontally, mounted in the upper part of Pusa boiler 1 and is fixed thereto. The steam receiving hole sheet 7 comprises a frame and horizontally arranged perforated sheets and vertically located perforated end sheets fixed thereon. Between the immersed 5 and the steam receiving 7 hole-shaped sheets is a steam space 6.

In FIG. 2 shows the baffle of the output manifold 4 formed by vertically arranged longitudinal sheet 10 and side sheets 9 connected to the side faces of the longitudinal sheet 10. The baffle of the input manifold 2 is formed by the vertically arranged longitudinal sheet 10 and side sheets 9 connected to the side faces of the longitudinal sheet 10 The lateral 9 and longitudinal 10 sheets of the baffles of the input 2 and output 4 collectors with the lower part are attached to the frame of the steam receiving hole sheet 7, with the upper part to the body of the steam generator 1.

On the side sheets 9 of the baffle of the inlet manifold 2 and on the side sheets 9 of the baffle of the outlet manifold 4, there is a perforation (not shown in Fig.), Which can be performed on both the windward and the leeward sides with respect to the movement of the steam flow inside the box of the steam receiving hole sheet 7. Perforation was also performed on the longitudinal sheet 10 of the inlet collector 2 baffle and on the longitudinal sheet 10 of the outlet manifold baffle 4. Perforation from the windward or from the leeward side, as well as size and quantity tversty forming perforations determined by the total steam flow from the steam generator, the flow rate in the flow path structural elements and its geometrical dimensions.

Perforation on the vertical sheets 9 and 10 of the baffle of the input 2 and output 4 collectors can be performed in any possible combination with respect to the direction of flow within the duct of the vapor receiving hole sheet 7. In particular, perforation can be performed on the side sheets 9 of the baffle of the input manifold 2 and on the side sheets 9 of the baffle of the output manifold 4 from the windward side with respect to the movement of the flow inside the duct of the steam receiving hole sheet 7; on the side sheets 9 of the baffle of the inlet manifold 2 and on the side sheets 9 of the baffle of the outlet manifold 4 on the leeward side with respect to the movement of the flow inside the duct of the steam receiving hole sheet 7; on the longitudinal sheet 10 of the baffle of the inlet manifold 2 and on the longitudinal sheet 10 of the baffle of the outlet manifold 4 from the windward side with respect to the movement of the flow inside the duct of the steam receiving hole sheet 7; on the longitudinal sheet 10 of the baffle of the inlet manifold 2 and on the longitudinal sheet 10 of the baffle of the outlet manifold 4 on the leeward side with respect to the movement of the flow inside the duct of the vapor receiving hole sheet 7.

At the same time, the joints of the longitudinal sheet 10 with the side sheets 9 of the input manifold baffle 2 and the joints of the longitudinal sheet 10 with the side sheets 9 of the baffle of the output manifold 4 are rounded (see Fig. 4).

The volume limited by the inner surface of the baffles of the inlet 2 and outlet 4 collectors, the outer surface of the inlet 2 and outlet 4 collectors, as well as the inner surface of the casing of the steam generator 1 above the baffles, is a continuation of the steam space 6.

The steam generator operates as follows.

The coolant enters the inlet manifold 2, passes through a bundle of horizontal heat exchange tubes 3 and exits through the outlet manifold 4. The coolant transfers heat to the working fluid located in the annulus, which is boiling. The resulting steam passes through the immersed hole sheet 5, the steam space 6 and enters the steam receiving hole sheet 7. Next, the steam through the holes in the steam receiving hole sheet 7 and the holes in the side 9 and longitudinal 10 sheets of the collector wall 2 and 4 enters the space bounded from above by the inner surface the case of the steam generator 1. Then the steam exits through the branch pipe for removing steam 8 from the case of the steam generator 1.

The use of perforated side 9 and longitudinal 10 sheets of inlet 2 and output 4 collector boxes of the steam receiving hole sheet 7, as well as the joints of the longitudinal sheets 10 with side sheets 9 of the input 2 and output 4 collectors rounded, reduces or eliminates the vorticity zone of the ascending mirrors vaporization vapor stream. This makes it possible to organize directed upward flow without the formation of areas with unacceptably high flow rates, as well as with horizontal and downward flow of steam. This ensures the normal operation of gravitational separation and, as a result, ensuring the normalized value of humidity of saturated steam at the outlet of the steam generator.

Thus, the hydraulic resistance of the steam exhaust duct is reduced and the operational reliability of the steam generator is increased.

Claims (5)

1. A steam generator comprising a housing, inlet and outlet manifolds with a horizontal bundle of heat exchanger tubes attached to them, an inlet manifold baffle consisting of vertically arranged side sheets and a longitudinal sheet, an outlet manifold baffle consisting of vertically arranged side sheets and a longitudinal sheet, immersed hole a sheet installed in the upper part of the housing a steam receiving hole sheet containing a frame and horizontally arranged sheets with perforation and vertically fixed thereon located end sheets with perforation, and a steam outlet pipe, characterized in that the input manifold baffle and the outlet manifold baffle of the steam receiving hole sheet are perforated, wherein the joints of the longitudinal sheet with the side sheets of the baffle of the input manifold and the joints of the longitudinal sheet with side sheets the outlet manifold walls are rounded. 2. The steam generator according to claim 1, characterized in that on the side sheets of the inlet manifold baffle and on the side sheets of the outlet manifold baffle, perforation is performed on the windward side with respect to the flow movement inside the duct of the vapor receiving hole sheet. 3. The steam generator according to claim 1, characterized in that on the side sheets of the inlet manifold baffle and on the side sheets of the outlet manifold baffle, perforation is performed on the leeward side with respect to the flow movement inside the duct of the vapor receiving hole sheet. 4. The steam generator according to claim 1, characterized in that on the longitudinal sheet of the baffle of the inlet manifold and on the longitudinal sheet of the baffle of the outlet manifold, perforation is made on the windward side with respect to the flow movement inside the duct of the vapor receiving hole sheet. 5. The steam generator according to claim 1, characterized in that on the longitudinal sheet of the baffle of the input manifold and on the longitudinal sheet of the baffle of the output manifold, perforation is performed on the leeward side with respect to the movement of the flow inside the duct of the vapor receiving hole sheet.

Images